JP3592159B2 - Television signal transmitter - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a television signal transmitter which is used in, for example, a CATV system and converts a signal in a television intermediate frequency band into a television signal having a broadcast channel frequency.
[0002]
[Prior art]
FIG. 2 shows a circuit configuration of a main part of a conventional television signal transmitter. A signal in a television intermediate frequency band (hereinafter, simply referred to as an intermediate frequency signal) is converted into a television signal of a broadcast channel frequency (hereinafter, simply referred to as a television signal). ), A first frequency converter 11 and a second frequency converter 12. These frequency converters 11 and 12 are incorporated in the same housing.
[0003]
The first frequency converter 11 and the second frequency converter 12 have the same configuration, and the first frequency converter 11 converts an intermediate frequency signal into a first intermediate frequency signal having a higher frequency. A first mixer 11a, a first local oscillator 11b that inputs a first local oscillation signal to the first mixer 11a, a second mixer 11c that converts the frequency of the first intermediate frequency signal into a television signal, A second local oscillator 11d for inputting a second local oscillation signal to the two-mixer 11c.
Similarly, the second frequency converter 12 also has a first mixer 12a, a first local oscillator 12b, a second mixer 12c, and a second local oscillator 11d.
[0004]
The contents (broadcast program contents) of the intermediate frequency signals input to the first mixers 11a and 12a of the frequency converters 11 and 12 are different from each other. Accordingly, the television signals output from the second mixers 11c and 12c are output at different channel frequencies. These television signals are mixed by a mixer 13 and transmitted to a CATV system subscriber via a cable (not shown).
[0005]
In the above configuration, since the frequency of the first intermediate frequency signal is set in advance to be a predetermined frequency, the frequencies of the first local oscillation signals output from the two first local oscillators 11b and 12b are the same. Become. Since the channels of the television signals output by the second mixers 11c and 12c are different from each other, the frequencies of the second local oscillation signals output by the second local oscillators 11d and 12d are different from each other by at least one channel. ing.
[0006]
[Problems to be solved by the invention]
In the above-described conventional television signal transmitter, the first local oscillation signals are set so as to have the same frequency, but in fact, they exactly match each other due to the variation in constants of components used for the first local oscillator. Nevertheless slightly different.
[0007]
For this reason, for example, the first local oscillator signal of the first frequency converter leaks and is input to the second frequency converter, or conversely, the second local oscillator signal of the second frequency converter leaks. When input to the first frequency converter, in each frequency converter, the first local oscillation signal and the second local oscillation signal are mixed in a first mixer or the like, and the difference between the frequencies is calculated. A signal is generated. The level of the difference signal increases as the frequency difference decreases, that is, as the frequencies of the first local oscillation signals are closer to each other, and appears as an interference signal near the video carrier of the television signal.
As a result, when such a television signal is received, a stripe pattern appears on the screen, and the image quality is significantly reduced.
[0008]
Accordingly, it is an object of the television signal transmitter of the present invention to eliminate interference caused by a signal of a frequency difference generated between respective first local oscillation signals in two frequency converters.
[0009]
[Means for Solving the Problems]
In order to solve the above problems, in the television signal transmitter of the present invention, the first and second frequencies for converting the frequency of a television signal of an intermediate frequency band into a television signal of a different broadcast channel and outputting the same. A frequency converter for converting the television signal of the intermediate frequency band into a television signal of a first intermediate frequency band having a frequency higher than the frequency of the television signal of the intermediate frequency band. A mixer, a first local oscillator for generating a first local oscillation signal and inputting to the first mixer, and frequency-converting the television signal of the first intermediate frequency band to a television signal of the broadcast channel. A second mixer, having a second local oscillator for generating a second local oscillation signal and inputting to the second mixer, the first local oscillator in the first frequency converter Parts and the frequency of the first local oscillation signal in frequency and said second frequency converter of the oscillating signal so different from each other 0.25MHz or more.
[0010]
In the television signal transmitter according to the present invention, the first frequency converter and the second frequency converter have a passband wider than a frequency band of the television signal in the first intermediate frequency band. Bandpass filters are respectively provided between the first mixer and the second mixer, and the frequency of the first local oscillation signal in the first frequency converter and the first local oscillation in the second frequency converter The frequency of the signal can be set to any frequency that is an integer multiple of 0.25 MHz from a predetermined reference frequency.
[0011]
Further, in the television signal transmitter according to the present invention, each of the frequency converters is provided with a PLL circuit individually controlling the respective first local oscillator, and a first local oscillation signal of the first frequency converter is provided. A microcomputer for storing frequency data for setting a frequency and a frequency of a first local oscillation signal in the second frequency converter is provided, and the microcomputer inputs the frequency data to each of the PLL circuits.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a television signal transmitter according to the present invention will be described with reference to FIG. The television signal transmitter according to the present invention includes a two-system frequency converter, a first frequency converter 1 and a second frequency converter that frequency-convert an input intermediate frequency band television signal into a broadcast channel television signal and output the converted signal. A second frequency converter 2, a third mixer 3 for mixing television signals of broadcast channels output from the first and second frequency converters 1 and 2, and a first and second frequency converter 1 And a microcomputer (referred to as an MPU) 4 for controlling the MPU 2 and the like. These frequency converters 1, 2 and the like are incorporated in the same housing (not shown) constituting a television transmitter.
[0013]
Here, the television signal in the intermediate frequency band is a television signal in an intermediate frequency band in a so-called television system. For example, in the US specification, a video intermediate frequency signal is 45.75 MHz, and an audio intermediate frequency signal is 41.25 MHz. It is a signal that becomes
The intermediate frequency television signal input to the first frequency converter 1 and the intermediate frequency television signal input to the second frequency converter 2 have different video and audio signals. are doing.
The television signal of the broadcast channel is a television signal assigned to the broadcast channel, and the frequency differs depending on the channel.
[0014]
The first frequency converter 1 and the second frequency converter 2 have the same configuration, and the first frequency converter 1 has an input amplifier 1a to which a television signal of an intermediate frequency band is inputted, A first mixer 1b for frequency-converting a television signal in the intermediate frequency band into a television signal in a first intermediate frequency band having a higher frequency, generates a first local oscillation signal, and inputs the signal to the first mixer 1b. A first local oscillator 1c, a first PLL circuit 1d for controlling the frequency of the first local oscillation signal, a band-pass filter 1e for passing the television signal in the first intermediate frequency band, and broadcasting the television signal in the first intermediate frequency band A second mixer 1f for converting a frequency into a television signal of a channel, a second local oscillator 1g for generating a second local oscillation signal and inputting the second local oscillation signal to the second mixer 1f, and a second for controlling the frequency of the second local oscillation signal P L circuit 1h, output amplifier 1i, an output filter 1j, which are connected as shown in FIG.
[0015]
Similarly, the second frequency converter 2 also includes an input amplifier 2a, a first mixer 2b, a first local oscillator 2c, a first PLL circuit 2d, a first intermediate frequency filter 2e, a second mixer 2f, and a second local oscillator. 2g, a second PLL circuit 2h, an output amplifier 2i, and an output filter 2j, which are connected as shown in FIG.
[0016]
Then, television signals of different intermediate frequency bands of a video signal and an audio signal are input to each of the input amplifiers 1a and 2a. The frequency of the television signal in the first intermediate frequency band (the frequency of the video carrier) is 1300 MHz as the reference frequency, and therefore, the frequency of the first local oscillation signal is 1254.25 MHz as the reference frequency. The frequency of the first local oscillation signal can be changed within a certain range, and the frequency is set by the first PLL circuits 1d and 2d. The minimum step frequency at that time is 0.0125 MHz.
[0017]
The bandpass filters 1e and 2e have a pass band of about 7 to 8 MHz (for example, 1293 MHz to 1301 MHz), which is wider than the band of the television signal of the first intermediate frequency band (4.5 MHz). The reason is to cope with variations in transmission characteristics in the pass band of the band-pass filters 1e and 2e. Further, the frequency of the television signal of the broadcast channel may be slightly shifted from the standard frequency and output. That's why. This shift amount is usually ± 0.1125 MH.
[0018]
The television signal of the broadcast channel output from the first frequency converter 1 and the television signal of the broadcast channel output from the second frequency converter 2 are set to have different broadcast channel frequencies. . This broadcast channel is determined by the CATV system.
Therefore, the frequency of the second local oscillation signal in the first frequency converter 1 differs from the frequency of the second local oscillation signal in the second frequency converter 2 by at least one channel.
[0019]
Further, the frequency of the second local oscillation signal is higher than the frequency of the television signal of the first intermediate frequency band by the frequency of the television signal of the broadcast channel, but the television signal of the broadcast channel is frequency dependent on the set broadcast channel. Are different from each other, so that the frequency can be changed from approximately 1350 MHz to 2350 MHz so as to correspond to the frequencies of all the channels. Then, the frequency of the second local oscillation signal is set by the second PLL circuits 1h and 2h. At this time, the minimum step frequency is 0.125 MHz.
[0020]
Each of the output filters 1j and 2j is constituted by a variable-frequency band-pass filter. The center frequency of the pass band of the output filter changes in accordance with the frequency of the television signal of the broadcast channel. It is linked with the frequency of the local oscillation signal.
[0021]
The two first PLL circuits 1d and 2d and the two second PLL circuits 1h and 2h have frequency data (specifically, variable data in each PLL circuit) for determining the frequencies of the first and second local oscillation signals. The frequency division ratio data of the frequency divider) is input from the microcomputer (MPU) 4. The MPU 4 has a memory therein, and stores data for frequency setting input from the input means 5 such as a keyboard, for example.
[0022]
In the above configuration, the frequency of the television signal in the first intermediate frequency band in one of the frequency converters, for example, the first frequency converter 1, is set to be the reference frequency (1300 MHz).
In this case, the frequency of the first intermediate frequency signal in the first frequency converter 1 is also set to be the reference frequency 1254.25 MHz (= 1300 MHz-45.75 MHz). This setting is made by the first PLL circuit 1d.
[0023]
On the other hand, the frequency of the first local oscillation signal in the second frequency converter 2 is higher than the frequency of the first local oscillation signal in the first frequency converter 1 by 0.25 MHz or more, for example, 0.5 MHz. It is set to be as high as 1254.75 MHz. This setting is also made by the first PLL circuit 2d. Therefore, the frequency of the television signal in the first intermediate frequency band in the second frequency converter 2 is 1300.5 MHz (= 45.75 MHz + 1254.75 MHz).
[0024]
As a result, the frequency difference between the first local oscillation signals in each of the frequency converters 1 and 2 is separated by 0.5 MHz. However, if the distance is 0.25 MHz or more, the level of the interfering signal becomes considerably low. Can be prevented.
In addition, in response to increasing the frequency of the first local oscillation signal in the second frequency converter 1 by 0.5 MHz, the frequency of the second local oscillation signal in the second frequency converter 2 The frequency is set to be 0.5 MHz higher than the frequency of the second local oscillation signal corresponding to the standard frequency of the channel.
[0025]
Here, if the frequency of the television signal of the broadcast channel output from the first frequency converter 1 is shifted by 0.1125 MHz higher than the standard frequency, the broadcast output from the second frequency converter 2 It is assumed that the frequency of the television signal of the channel is shifted by 0.1125 MHz lower than the standard frequency. Then, the frequency of the first local oscillation signal in the first frequency converter 1 becomes 1254.3625 MHz (= 1254.25 MHz + 0.1125 MHz), and the frequency of the first local oscillation signal in the second frequency converter 2 becomes 1254.6375 MHz. (= 1254.75 MHz−0.1125 MHz), and the difference is 0.275 MHz. As a result, the frequency difference between the first local oscillation signals is 0.275 MHz, which satisfies 0.25 MHz or more, so that the level of the interference signal can be reduced.
[0026]
By the way, the pass band of the band-pass filters 1e and 2e is wider than the band of the television signal of the first intermediate frequency band. This is because the television signal of the output broadcast channel is made as flat as possible by matching the band of the television signal of the first intermediate frequency band. In order to do so, the difference between the frequency of the first local oscillation signal in the first frequency converter 1 and the frequency of the first local oscillation signal in the second frequency converter 2 is kept at 0.25 MHz or more, and On the other hand, the frequency is shifted and set to a frequency that is an integer multiple of 0.25 MHz.
[0027]
As a result, the frequency of the television signal in the first intermediate frequency band shifts, and the frequency of the second local oscillation signal also shifts by the same amount corresponding to the shift amount. Accordingly, the frequency of the television signal of the output broadcast channel does not change and is maintained at the original frequency.
The frequency data for determining the shift amount is input from the microcomputer 5 to the first PLL circuits 1d and 2d and the second PLL circuits 1h and 2h.
[0028]
【The invention's effect】
As described above, in the television signal transmitter of the present invention, the first and second frequency converters convert the input intermediate frequency band television signal into the first intermediate frequency band television signal. A first mixer for performing frequency conversion, a first local oscillator for inputting the first local oscillation signal to the first mixer, and a second for frequency-converting a television signal of the first intermediate frequency band into a television signal of a broadcast channel. A second local oscillator for inputting the second local oscillator signal to the second mixer, the frequency of the first local oscillator signal in the first frequency converter and the first local oscillator signal in the second frequency converter. Since the frequencies of the local oscillation signals are different from each other by 0.25 MHz or more, the level of the interfering signal due to the frequency difference between the first local oscillation signals is considerably reduced, and the deterioration of the video quality can be sufficiently prevented.
[0029]
Further, the television signal transmitter according to the present invention is characterized in that the first frequency converter and the second frequency converter have a band-pass filter having a pass band wider than the frequency band of the television signal in the first intermediate frequency band. Are provided between the first mixer and the second mixer, respectively, the frequency of the first local oscillation signal in the first frequency converter and the frequency of the first local oscillation signal in the second frequency converter are predetermined. Since the frequency can be set to any of frequencies that are an integer multiple of 0.25 MHz from the reference frequency, the television signal of the first intermediate frequency band is placed in a flat band of the pass band of the band-pass filter. The band can be matched. Therefore, the output television signal of the broadcast channel can be made flat.
[0030]
Further, in the television signal transmitter of the present invention, each frequency converter is provided with a PLL circuit for individually controlling each first local oscillator, and the frequency of the first local oscillation signal in the first frequency converter and A microcomputer for storing frequency data for setting the frequency of the first local oscillation signal in the second frequency converter is provided, and the frequency data is input from the microcomputer to each PLL circuit. The frequency can be set reliably.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a configuration of a television signal transmitter according to the present invention.
FIG. 2 is a circuit diagram illustrating a configuration of a conventional television signal transmitter.
[Explanation of symbols]
1 first frequency converter 1a input amplifier 1b first mixer 1c first local oscillator 1d first PLL circuit (PLL circuit)
1e Band-pass filter 1f Second mixer 1g Second local oscillator 1h Second PLL circuit 1i Output amplifier 1j Output filter 2 Second frequency converter 2a Input amplifier 2b First mixer 2c First local oscillator 2d First PLL circuit (PLL circuit)
2e Band-pass filter 2f Second mixer 2g Second local oscillator 2h Second PLL circuit 2i Output amplifier 2j Output filter 3 Third mixer 4 Microcomputer 5 Input means

Claims (3)

A first and a second frequency converter for converting the frequency of the intermediate frequency band television signal into a television signal of a different broadcast channel and outputting the converted signal, wherein each of the frequency converters includes the intermediate frequency band television signal; A first mixer for converting the frequency of the television signal of the intermediate frequency band into a television signal of a first intermediate frequency band higher than the frequency of the television signal of the intermediate frequency band, and generates a first local oscillation signal and the first mixer A first local oscillator for input, a second mixer for frequency-converting the television signal of the first intermediate frequency band to a television signal of the broadcast channel, and a second mixer for generating a second local oscillation signal And a second local oscillator for inputting the first local oscillation signal in the first frequency converter and the first local oscillation signal in the second frequency converter. Television signal transmitter of the frequency, characterized in that the mutually varied over 0.25 MHz. The first frequency converter and the second frequency converter and a bandpass filter having a pass band wider than the frequency band of the television signal of the first intermediate frequency band respectively the first mixer and the Provided between the second mixer, the frequency of the first local oscillation signal in the first frequency converter and the frequency of the first local oscillation signal in the second frequency converter with respect to a predetermined reference frequency 2. The television signal transmitter according to claim 1, wherein both of the frequencies can be set to any of integer frequencies separated by 0.25 MHz. Each of the frequency converters is individually provided with a PLL circuit for controlling each of the first local oscillators, and the frequency of the first local oscillation signal in the first frequency converter and the first local oscillator signal in the second frequency converter are controlled separately. 3. The television signal transmission according to claim 2, wherein a microcomputer for storing frequency data for setting a frequency of the local oscillation signal is provided, and the frequency data is input from the microcomputer to each of the PLL circuits. Machine.

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